Structure comprising a getter layer and an adjusting sublayer and fabrication process

ABSTRACT

The structure comprises at least a device, for example a microelectronic chip, and at least a getter arranged in a cavity under a controlled atmosphere delineated by a substrate and a sealing cover. The getter comprises at least one preferably metallic getter layer, and an adjustment sub-layer made from pure metal, situated between the getter layer and the substrate, on which it is formed. The adjustment sub-layer is designed to modulate the activation temperature of the getter layer. The getter layer comprises two elementary getter layers.

BACKGROUND OF THE INVENTION

The invention relates to a structure comprising a closed cavity under acontrolled atmosphere wherein there are arranged at least a device and agetter comprising at least one getter layer, the cavity being delineatedby a substrate and a sealing cover.

STATE OF THE ART

Integration in a vacuum enables the performances of numerous devices,for example microelectronic devices such as Micro Electra MechanicalSystems (MEMS) to be improved. However, the use of encapsulation in avacuum gives rise to a number of problems, and in particularpreservation of the vacuum level with time and the quality of theencapsulated atmosphere.

In this direction, non evaporable getter (NEG) materials deposited inthin layers have been the subject of numerous publications. Thesematerials react and capture numerous gases with which they are incontact by formation of an oxide, a hydride or then again by simplesurface adsorption. In this way, desorption of the materials delineatinga cavity in a vacuum is compensated by the getter material layer whichadsorbs and/or absorbs the desorbed elements of the other materials.

Integration of non-evaporable getter materials within an encapsulationstructure has been described in particular in U.S. Pat. No. 6,923,625.This patent describes the use, on a substrate, of a getter comprising areactive layer covered by a protective layer. In this document, theprotective layer prevents the reactive layer from reacting with theoutside environment at ambient temperature. The reactive layer of thegetter only acts when its activation temperature is reached, atemperature above which the atoms of the reactive layer diffuse throughthe protective layer and absorb a part of the gases of the surroundingenvironment. The activation temperature is an intrinsic characteristicof the getter material.

In a general manner, known monolayer or multilayer getters have anabsorption or adsorption capacity that is limited to a set temperaturerange. In the microsystems field, it is advantageous to be able todispose of a getter material that is adaptable to the constraintsimposed by the technological methods indispensable for producing thedevice. The constraints can be thermal, in which case a match must bemade between the getter material activation temperature and theformation process of a cavity closed by sealing, for example of twosubstrates on a seal. Furthermore, the getter material has to be able towithstand the gaseous environments that are used in formation of thedevice while at the same time remaining reactive when the device is usedin its closed cavity.

The document WO 03/028096 describes production, on a substrate, of agetter in the form of a thin film constituted by a titanium filmdeposited on a palladium film. The titanium getter film is formed on anelectromagnetic shielding layer made of aluminium or copper.

OBJECT OF THE INVENTION

The object of the invention is to produce a structure wherein the getterpresents an optimum pumping capacity in a required temperature range.

According to the invention, this object is achieved by the fact that anadjustment sub-layer of the activation temperature of the getter layeris situated between the getter layer and the substrate and/or thesealing cover whereon it is formed, and that the getter layer is formedby a plurality of elementary getter layers of different compositionsarranged above the adjustment sub-layer.

It is a further object of the invention to provide a method forproducing such a structure.

BRIEF DESCRIPTION OF THE DRAWINGS

Other advantages and features will become more clearly apparent from thefollowing description of particular embodiments of the invention givenfor non-restrictive example purposes only and represented in theappended drawings, in which:

FIG. 1 represents a schematic cross-sectional view of a structureaccording to the prior art,

FIGS. 2 and 3 represent schematic cross-sectional views of thestructures according to the invention,

FIG. 4 represents a schematic cross-sectional view of stacking of amultilayer getter of a structure according to the invention.

DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION

As illustrated in FIG. 2, a structure 1 able to be a microelectronicschip conventionally comprises at least a device 3, for example ofmicroelectronics type, arranged in a sealed cavity delineated by twosubstrates 2 and 4 and by a closed peripheral sealing joint 5. Thetightness of the cavity is provided by sealing joint 5 situated betweenthe substrates and that surrounds device 3. Microelectronics device 3 isfor example formed on first substrate 2. The cavity is generally at anegative pressure with respect to the outside atmosphere, preferably ina vacuum or under a controlled pressure of nitrogen or argon.

Conventionally, the height of the cavity is defined by the height ofsealing joint 5 that surrounds device 3 (FIG. 1). However, secondsubstrate 4 can be structured so as to form a cover comprising a thinnercentral part so as to increase the volume of the cavity.

Second substrate 4 is for example made from silicon, oxidized ornitrided silicon or glass. First substrate 2 is for example made fromsilicon or any other semi-conducting material, except for galliumarsenide (GaAs), or from another material on which an already formeddevice can be integrated.

In another embodiment illustrated in FIG. 3, structure 1 comprises atightly-sealed closed cavity that is delineated by substrate 2 and by anencapsulation layer 11. The tightness of the structure is then ensuredby the adhesion between encapsulation layer 11 and substrate 2. Theencapsulation layer then acts as sealing cover, like substrate 4 ofFIG. 1. The sealing cover can comprise other layers in addition to theencapsulation layer. In the embodiment illustrated in FIG. 3, the heightof the cavity is defined by the thickness of sacrificial material 12deposited on the substrate.

In order to ensure the perenniality of the negative pressure leveland/or of the quality of the atmosphere inside the cavity, the cavitycomprises at least one getter 6 on at least one of its inside walls.Getter 6 is of multilayer type and comprises at least one adjustmentsub-layer 8 situated between one of substrates 2 or 4 and a getter layer7 which conventionally forms the adsorbent and/or absorbent layer.Getter layer 7 is for example made from a metallic material preferablychosen to have a high nitrogen pumping capacity, this gas being commonlyused for encapsulation of devices. If getters 6 present differentactivation temperatures from one another, it is advantageous todifferentiate the latter, for example separating them into getters 6 aand additional getters 6 b (FIGS. 3 and 4) or first getters 6 a andsecond getters 6 b.

For example purposes, in FIG. 4, getter 6 is formed on substrate 2. Anadhesion sub-layer 9 is advantageously deposited on substrate 2 beforeadjustment sub-layer 8. Adhesion sub-layer 9 is designed to enhancebonding of adjustment sub-layer 8 on substrate 2. For a siliconsubstrate, adhesion sub-layer 9 is typically made for example fromtitanium or zirconium, by means of any suitable technique, and presentsa thickness advantageously comprised between 20 and 100 nm.

Adjustment sub-layer 8, situated beneath and in contact with getterlayer 7, is designed to enable the activation temperature of the getterlayer to be modulated, i.e. it enables the temperature at which thegetter layer reacts with the atmosphere present inside the cavity to bemodulated. Adjustment sub-layer 8 is preferably made from Cu, Ni, Pt,Ag, Ru, Cr, Au, Al and presents a thickness preferably comprised between50 and 500 nm when the thickness of getter layer 7 a is about a fewhundred nanometers, typically between 100 and 2000 nm. The thickness ofthe adjustment sub-layer can be reduced to a few tens of nanometers,typically between 10 and 90 nm, when the thickness of getter layer 7 ais a few hundred nanometers, typically between 100 and 900 nm. Forexample purposes, an adjustment sub-layer 8 of 30 nm is sufficient for agetter layer 7 a of 300 nm. The minimum thickness of adjustmentsub-layer 8 is approximately between 5% and 10% of the thickness ofgetter layer 7 a, for example equal to 8%. More generally, adjustmentsub-layer 8 is for example made from a metallic material, except forpalladium, deposited in pure body state which, like platinum forexample, is chemically neutral with respect to getter layer 7 in therequired activation range. Adjustment sub-layer 8 can also be made froma material that becomes neutral or that becomes a trap for certainchemical species, for example oxygen, after interaction with getterlayer 7. This is in particular the case of copper or nickel, which areable to form an intermetallic compound of Ti₂Cu or Ti₂Ni type with atitanium getter layer, a compound in which oxygen is partially soluble.Adjustment sub-layer 8 can also be made from a material which has astrong chemical affinity for one or more chemical elements from amongcarbon, oxygen and nitrogen. The sub-layer can for example be made fromchromium or aluminium. In the latter case, aluminium sub-layer 8 acts asprotection for getter layer 7 when exposed to the ambient air, therebyincreasing the storage time of the getter without impairment of itsproperties, as sub-layer 8 prevents the growth of an oxide layer. Thisarchitecture is particularly advantageous for obtaining constant pumpingcapacities after exposure to the ambient air of several months.

In the presence of an aluminium sub-layer, the getter is directly activewithout any pre-treatment prior to its use. The activation temperatureof a getter stack comprised of an aluminium adjustment sub-layer 8 and atitanium getter layer 7 a is about 400° C.

Furthermore, in a particular embodiment, a protective layer 10 can bearranged on getter layer 7 to protect the getter. Getter 6 can thusmaintain its pumping capacity after prolonged exposure to the ambientair or be protected from aggressive technological processes which coulddamage the latter. For example, if an aluminium adjustment sub-layer 8enables getter 6 to be preserved from the ambient air, a thin layer ofchromium acting as protective layer 10 can be used on getter layer 7.The thickness of protective layer 10, for example made from chromium,can be comprised between 10 nm and 50 nm, and advantageously equal to 20nm. Adding a protective layer 10 contributes to increasing theactivation temperature of the getter slightly, typically by about twentydegrees Celsius for a 20 nm chromium layer.

In another embodiment, if the getter is damaged at the surface either bythe oxidation occurring during storage in the ambient air or by theaggressive technological processes to which it is exposed duringproduction of the structures, regeneration pre-treatment can easily beimplemented. Regeneration pre-treatment consists in exposing the getterin a secondary vacuum, advantageously at a pressure of about 10⁻⁷ mbaror under a partial pressure of a neutral gas not absorbed by the getter,and at a temperature close to its activation temperature for a durationthat enables it to absorb the layer which impairs its pumping capacity.The getter is then cooled to the ambient temperature, typically atemperature close to 20° C. In a privileged embodiment that can becombined for example with the foregoing embodiment, before it is exposedto the ambient air, the getter is exposed to a known gas, preferablynitrogen, which will adsorb at the surface and thereby protect thegetter temporarily against the ambient air. For example, a temperatureof 350° C. is applied for a few hours to regenerate the set of getters 6a described in the present invention.

It may be advantageous to add sacrificial getters deposited on the wholesurface of a substrate, for example in the heat treatment vacuumchamber. The sacrificial getter is chosen to have a lower activationtemperature than that of getter 6 (or of getters 6 a, 6 b) that has tobe treated when regeneration pre-treatment is performed. The sacrificialgetter then serves the purpose of improving the quality of the vacuum inthe chamber. Before treatment of the getters is performed, it may beadvantageous to flush the chamber with a neutral gas such as argon inorder to limit the partial pressures of the residual gases that areliable to react with the getter. The getters can then be subjected tooxidizing atmospheres with which they react and then be regenerated asdescribed above.

Typically, these oxidizing atmospheres are generated when thetechnological process steps are performed, in particular the steps ofeliminating a sacrificial layer of polymer resin. In conventionalmanner, when producing a structure illustrated in FIG. 3, gettermaterial 7 is subjected to such oxidizing atmospheres. Indeed, getter 6a and device 3 are encapsulated by a sacrificial resin 12 and then by anencapsulation layer 11. The sacrificial resin is shaped for example byheating before encapsulation layer 11 is deposited. The device andgetter are released from the layer of sacrificial resin 12 from holesmade in encapsulation layer 11. For example, sacrificial resin 12 can bea standard positive-polarity resin used in photolithography and/or anegative-polarity resin of polyimide type. These resins can both bedestroyed with a heat treatment in an oxidizing atmosphere. It is thenparticularly interesting to choose a getter 6 composed of at least oneadjustment sub-layer 8 and at least one getter layer 7 such that theactivation temperature is greater than the baking temperature of thesacrificial resin. Pollution of the getter by the contaminantsoriginating from the polymer, thereby reducing or even annulling itspumping capacity, is in this way prevented.

This embodiment mode is particularly advantageous for fabrication ofMEMS and Infra-Red detectors in order to burn the resin layers on whichelements of the microdevice and its encapsulation layer are constructed.

The getter materials are generally exposed to a generally oxidizing dryprocess treatment with a view to enhancing the propensity of thesubstrate on which the getter is deposited to direct sealing. Thistreatment thus contributes to increasing the adhesion energy between thetwo substrates which delineate the cavity when the latter are broughtinto contact. In order to limit the effect of the oxidizing treatment, aprotective layer 10 of chromium is then recommended. The choice of agetter 6 a with a low activation temperature, advantageously lower than300° C., enables both the sealing to be consolidated and the getter tobe activated at a temperature close to 400° C. The getter is therebyactivated when the consolidation treatment of the sealing between thetwo substrates is performed.

Adjustment sub-layer 8 preferably has a coefficient of thermal expansionsubstantially comprised between 5*10⁻⁶/° C. and 20*10⁻⁶/° C., or even23*10⁻⁶/° C. for aluminium, and a ratio between its formationtemperature Te and its melting temperature Tf (in degrees Kelvin)substantially comprised between 0.1 and 0.3. The activation temperatureof the associated getter layer 7 is then an increasing function of thecoefficient of expansion of adjustment sub-layer 8 and of ratio Te/Tfand varies in decreasing manner with the melting temperature ofadjustment sub-layer 8. It is known that the coefficient of expansion ofa metal decreases when the melting temperature of said metal increases.Over a limited temperature range, it is possible to empiricallydetermine the equation that links the activation temperature of getter 6and the melting temperature of the metal that forms activation sub-layer8. In particular for the following metals Ru, Cr, Pt, Ni, Au, Cu, Ag,and Al, the equation linking getter activation temperature Ta to meltingtemperature Tf of the material constituting the adjustment sub-layer is:Ta=−0.0727*Tf+447, in which Ta and Tf are expressed in degrees Celsius.In this case, deposition is performed at a temperature close to ambienttemperature on a silicon substrate. Although this equation has nophysical meaning, it enables the phenomenon to be accounted for.

The effect of adjustment sub-layer 8 on getter layer 7 can beinterpreted in the following manner. The getter effect in a metallicmaterial deposited as a thin layer takes place by diffusion of theadsorbed chemical species to the inside of the layer. The getter effectis therefore linked to the microstructure, i.e. to the size, the shapeand the orientation of the grains that compose the metallic material.Absorption of the chemical species from the surface to the inside of thegetter takes place by diffusion along the grain boundaries. Thiscorresponds to a thermally activated phenomenon that takes place atrelatively low temperature in comparison with diffusion of the speciesin the grains. The structures that are most liable to present a gettereffect are therefore those for which the grains are columnar and ofsmall size, thereby enhancing diffusion at the grain boundaries. It ismoreover known that the deposition structure depends to a great extenton the ratio between the temperature of the substrate on which the metalis deposited, i.e. the formation temperature (Te), and the meltingtemperature of the latter (Tf), i.e. the ratio Te/Tf (in degreesKelvin). The Movchan and Demchisin diagrams (B. A. Movchan, A. V.Demchishin, 1969, Phys. Met. Metallogr., 28, p. 83) on the one hand andthose of Thornton (J. A. Thornton, 1986, J. Vac. Sci. Technol., A4(6),p. 3059) on the other hand provide a forecasted mapping of themicrostructure according to the ratio Te/Tf and to the pressure. It isapparent according to these diagrams that the zone where the structureof the deposit is of columnar type starts from 0.3 Tf (Tf in degreesKelvin). For Movchan and Demchisin, below this value the structure is inthe form of domes separated by intercolumnar gaps, and above 0.5 Tf thestructure becomes more isotropic and equiaxial. Between 0.3 Tf and 0.5Tf the columnar grains become larger. It is the surface mobility of theatoms, limited at low temperature, which enables the structures obtainedunder these conditions to be explained. The temperatures that define thetransitions between the different types of structure (0.3 Tf and 0.5 Tf)are approximate and act as guidelines only but they do strictly speakinghave to be defined empirically for each metal.

On account of the foregoing, if different adjustment sub-layers 8 aremade with different metals but under the same temperature conditions Teand pressure conditions, the grain size increases when the ratio Te/Tfincreases, For the same formation temperature Te, a ruthenium sub-layerwill therefore present a thinner microstructure, and therefore moregrain boundaries, than an aluminium sub-layer. Growth of getter layer 7on sub-layer 8 is partially controlled by the mobility of the gettermaterial atoms at the surface of adjustment sub-layer 8. Due to itsmicrostructure (preferential germination of getter layer 7 at the grainboundaries, triple nodes or nodes between the domes of the underlyingstructure) and/or its high melting temperature, a ruthenium sub-layer 8could limit surface migration of the getter metal thereby leading to athinner structure of the latter than in the opposite case where getterlayer 7 is deposited on aluminium.

According to this reasoning, it is therefore possible to modulateactivation temperature Ta of getter layer 7 for one and the sameadjustment sub-layer 8. The microstructure of adjustment sub-layer 8simply has to be adjusted according to its formation temperature Te,while remaining within a temperature range that will give the adjustmentsub-layer a sufficiently thin structure for the getter to be able to beactivated by a diffusion process mostly taking place at the grainboundaries.

In the structures that comprise getters 6 having different activationtemperatures from one another, getters 6 can be divided into at leastgetters 6 a and additional getters 6 b. In this instance, it is notcompulsory for the getter to comprise a getter layer 7 formed by atleast two elementary layers 7 a and 7 b.

Thus, for a structure that comprises at least one getter 6 a and anadditional getter 6 b inside a closed cavity, it is possible to achieveat least one getter 6 a and an additional getter 6 b having differentactivation temperatures simply and in industrial manner. The adjustmentsub-layer of getter 6 a for example presents a larger grain structurethan the part of the adjustment sub-layer of additional getter 6 b. Inother words, the grains of adjustment sub-layer 8 of getter 6 a arelarger than the grains of adjustment sub-layer 8 of additional getter 6b. The getter layer deposited simultaneously on the two adjustmentsub-layers thus presents a finer crystalline microstructure inadditional getter 6 b than in getter 6 a. It is therefore possible toobtain two getters 6 a and 6 b having two different activationtemperatures using the same material for the adjustment sub-layers ofthe two getters 6 a and 6 b, but taking care to fabricate the twosub-layers at different temperatures. The two getters 6 a and 6 btherefore have two different activation temperatures, whether thematerials constituting getter layers 7 are identical or not for the twogetters.

It is also possible to obtain two getters 6 a and 6 b having twodifferent activation temperatures using the same material for the getterlayer and two different materials as far as the adjustment sub-layer isconcerned.

This constitutes an additional technological advantage, since, with thesame nature of adjustment sub-layer, it becomes possible to control thegetter activation temperature. It can also be envisaged to produceseveral adjustment sub-layers on one and the same substrate bysuccessive deposition, photolithography and etching operations. Getterlayer 7, and protective layer 10 if applicable, are then successivelydeposited and patterned by photolithography and etching. Getter layer 7,and protective layer 10 if applicable, can then be identical for all thegetters.

Adjustment sub-layer 8 being situated between the getter layer andsubstrate 2, it also enables the chemical interactions between substrate2 and getter layer 7 to be eliminated. The pumping capacity of getterlayer 7 is thereby preserved.

Getter layer 7 deposited on adjustment sub-layer 8 is for example madefrom Ti or Zr and presents a thickness comprised between 100 and 2000nm. The activation temperature of the getter layer, without the actionof adjustment sub-layer 8, is higher than 425° C. and close to 450° C.With the action of adjustment sub-layer 8, the activation temperature ofgetter layer 7 varies according to the nature of this adjustmentsub-layer 8. The activation temperature of titanium or zirconium getterlayer 7 can vary increasingly, substantially between 275 and 425° C.,depending on adjustment sub-layer 8.

The table below (table 1) gives values of the activation temperature ofa getter 6 according to the nature of its adjustment sub-layer 8 forexample purposes for a titanium getter layer 7. All the depositions areperformed on a silicon substrate at an identical temperature Te, closeto the ambient temperature.

Nature of adjustment sub-layer 8 Activation temperature Ru 275° C. Cr300° C. Pt 325° C. Ni 350° C. Au 365° C. Cu 375° C. Ag 380° C. Al 400°C.

As the melting temperature of zirconium is higher than that of titanium,the zirconium deposition microstructure has to be thinner than that oftitanium. The activation temperatures presented in table 1 shouldtherefore be substantially lower with a zirconium getter sub-layer thanwith a titanium getter layer.

Getter layer 7 is advantageously formed by stacking of a plurality ofelementary getter layers, preferably two, 7 a, 7 b, of differentchemical compositions. The elementary getter layers are deposited on topof one another on adjustment sub-layer 8. In the case where twoelementary getter layers 7 a, 7 b are used, first elementary getterlayer 7 a, in contact with adjustment sub-layer 8, presents a higheractivation temperature than that of second elementary getter layer 7 bthat covers it. Elementary getter layers 7 a, 7 b thus present adecreasing activation temperature the farther they are located away fromadjustment sub-layer 8. Thus, when second getter layer 7 b is saturated,heat treatment at the activation temperature of first elementary getterlayer 7 a enables second elementary getter layer 7 b to be regenerated.It is therefore possible to adjust the activation temperature of firstelementary getter layer 7 a by means of adjustment sub-layer 8 to obtainthe required activation temperature, taking account of the activationtemperature of second elementary getter layer 7 b.

First elementary getter layer 7 a, in contact with adjustment sub-layer8, is preferably made from titanium and has a thickness that ispreferably comprised between 100 and 1000 nm. Second elementary getterlayer 7 b, deposited on elementary getter layer 7 a, is then for examplemade from zirconium and has a thickness preferably comprised between 200nm and 1000 nm.

The use of two different elementary getter layers 7 a, 7 b isparticularly advantageous for reconditioning the chip in the course ofits lifetime by activation of first layer 7 a.

Furthermore, adjustment sub-layer 8 of the multilayer getter can bechosen such as to increase the reflectivity of the getter to infraredradiation, typically when the getter is chosen as being an infraredradiation reflector (for certain specific applications). This reflectingfunction is advantageously chosen, in particular according to the natureof the material of adjustment sub-layer 8 which is advantageously madefrom copper or aluminium. For example in a bolometer, this reflectivityis sufficient to place the getter as IR reflector. In this case, getter6 presents another essential function: IR reflector. If the layer ismade from titanium, it already has a certain reflectivity to infraredradiation. The use of a suitable adjustment sub-layer then enables thereflectivity to infrared radiation of the whole of the getter to beincreased.

Multilayer getter 6 comprising at least adjustment sub-layer 8, getterlayer 7 and adhesion sub-layer 9 if applicable can be formed anywhere inthe cavity and for example on substrate 2 or 4 before or after formationof micro-electronic device 3. Such a getter 6 can also be formed on thetwo substrates 2 and 4 delineating the cavity.

Adhesion sub-layer 9 is advantageously deposited by any suitabletechnique, preferably by evaporation on substrate 2. Adjustmentsub-layer 8 and then first and second elementary getter layers (7 a, 7b) are then successively deposited, advantageously by evaporation, onadhesion sub-layer 9. Advantageously, the deposition steps of thedifferent layers are performed on the same deposition equipment.Adhesion sub-layer 9 can contribute to improving the quality of thevacuum in this deposition chamber when the material forming this layer(for example Ti or Zr) has getter properties.

Getter 6 can then be patterned in conventional manner, for example bylithography and dry process etching, advantageously by a non-reactiveplasma and/or by wet process etching, so as to locate precisely theareas in which getter layers 7 are required. The adhesion of thepositive resin used for lithography on getter layer 7 can be improved ifnecessary by adding an adhesion promoter, advantageouslyhexadimethylsilazane (HDMS).

Layers 7, 8, 9 and 10 are etched from usual liquid chemical reagentsand/or by a neutral plasma according to the materials used.Advantageously getter layer 7 and protective layer 10 can be etched bywet process and the rest of the stack by neutral plasma when wet etchingof the adjustment sub-layer is not easy, for example for platinum andruthenium. The two etching modes can also be used when anincompatibility exists between the etching reagents of the differentlayers. This incompatibility can lead to over-etching phenomena or evento impairment of certain layers.

The step of removing the positive resin and all or part of the promoterif used can be performed by means of a conventional product used in themicro-electronics industry and advantageously followed by cleaning withfuming nitric acid when the latter does not affect sub-layer 8. At theoutcome, dry etching with a non-reactive plasma enables pollutants orresidues originating from previous technological steps and present atthe surface of getter layer 7 to be eliminated if necessary.

The getter can also be patterned by a lift-off process when depositionis performed. A photosensitive dry film of negative polarity islaminated on the substrate. The dry film with a thickness comprisedbetween 5 and 50 μm, advantageously equal to 15 μm, is exposed anddeveloped by means of a conventional photolithography step. The assemblyis then subjected to secondary vacuum treatment for the purpose ofeliminating the residues of the development. Deposition of the getter isthen performed, for example by sputtering, advantageously byevaporation. Removal of the non-exposed dry film is then performed bymeans of a specific product which does not modify the properties of thegetter material.

By means of the fabrication methods described above, it is possible tosuccessively achieve several getters 6 presenting different activationtemperatures on one and the same substrate and/or in one and the samecavity. In the case where patterning of getter 6 is achieved by chemicaletching, it is advantageous to deposit and pattern the differentadjustment sub-layers 8 of the different getters. Getter layer 7 is thendeposited, and is then patterned by chemical etching. As adjustmentlayer 8 and getter layer 7 are not produced immediately after oneanother and on the same equipment, it is preferable to use aregeneration pre-treatment as described in the above.

In the case where patterning of getter 6 is achieved by lift-off,successive depositions of getters 6 can be performed by laminating a dryfilm on an already formed getter. The activation temperature of severaldifferent getters can then be adjusted in a single structure.

The surface of the getter being able to be adjusted, the pumpingcapacity of each getter in terms of number of moles adsorbed or absorbedcan be controlled, which enables the pressure inside the cavity thatcontains the getters to be modulated.

The invention claimed is:
 1. A structure having a closed cavitydelineated by a substrate and a sealing cover, said cavity containing agetter comprising, on the substrate and/or the sealing cover: anadjustment sub-layer made from a metallic material selected from thegroup consisting of Ru, Cr, Pt, Ni, Cu, Al, and Au; and a plurality ofelementary getter layers of different compositions, each getter layerhaving a distinct activation temperature, wherein the elementary getterlayers present an activation temperature decreasing with distance fromthe adjustment sub-layer, wherein a thickness of the adjustmentsub-layer is substantially between 10 and 90 nm.
 2. The structureaccording to claim 1, wherein an adhesion sub-layer chosen from titaniumand zirconium is arranged between the adjustment sub-layer and thecorresponding substrate and/or cover.
 3. The structure according toclaim 1, wherein a thickness of the adjustment sub-layer issubstantially between 50 and 500 nm.
 4. The structure according to claim1, wherein each elementary getter layer is selected from the groupconsisting of titanium and zirconium.
 5. The structure according toclaim 1, wherein a thickness of the getter layer is substantiallybetween 100 and 2000 nm.
 6. The structure according to claim 1,comprising at least an additional getter distinct from the getter andhaving a different activation temperature of the getter.
 7. Thestructure according to claim 6, wherein: materials of the adjustmentsub-layers of the getter and of the additional getter are identical; andmaterials of the getter layers of the getter and of the additionalgetter are different.
 8. The structure according to claim 6, wherein:materials of the getter layers of the getter and of the additionalgetter are identical; and materials of the adjustment sub-layers of thegetter and of the additional getter are different.
 9. Structureaccording to claim 6, wherein: materials of the getter layers of thegetter and of the additional getter are identical; and the adjustmentsub-layers of the getter have a crystalline microstructure differentfrom a crystalline microstructure of the adjustment sub-layers of theadditional getter.
 10. The structure according to claim 1, wherein: afirst elementary getter layer is made of Ti₂Cu and/or Ti₂Ni; a secondelementary getter layer is made of titanium covering the firstelementary getter; and the adjustment sub-layer is selected from thegroup consisting of Cu and Ni.
 11. A structure having a closed cavitydelineated by a substrate and a sealing cover, said cavity containing afirst getter comprising a first adjustment sub-layer covered by a firstgetter layer; and an additional getter comprising an additionaladjustment sub-layer covered by an additional getter layer, wherein: theadditional adjustment sub-layer has a crystalline microstructuredifferent from a crystalline microstructure of the first adjustmentsub-layer; the first getter has an activation temperature different froman activation temperature of the additional getter; and the additionalgetter is distinct from the first getter.
 12. The structure according toclaim 11, wherein: materials of the adjustment sub-layers of getter andof the additional getter are identical; and materials of the getterlayers of the getter and of the additional getter are different.
 13. Thestructure according to claim 11, wherein: materials of the getter layersof the getter and of the additional getter are identical; and materialsof the adjustment sub-layers of the getter and of the additional getterare different.
 14. A structure having a closed cavity delineated by asubstrate and a sealing cover and containing a getter with an activationtemperature, comprising successively, on the substrate and/or thesealing cover: an adjustment sub-layer made from a metallic materialselected from the group consisting of Ru, Cr, Pt, Ni, Cu, Al, and Au, agetter layer, and a protective layer, wherein a thickness of theadjustment sub-layer is substantially between 10 and 90 nm.
 15. Thestructure according to claim 14, wherein the protective layer ischromium.